Abstract: An insulated glass unit is described and includes at least a first glass layer, a second glass layer and a third glass layer disposed therebetween. The third glass layer is separated from the first glass layer and the second glass layer by first and second sealed gap spaces. The third glass layer has a low CTE as compared to the CTE of the first and/or second glass layers. In some instances, the third glass layer has a CTE of less than 70×10?7/° C. over a temperature range of 0-300° C.

Abstract: Various embodiments are provided for an isolating fenestration assembly including a triple pane IGU configured with chambers between the panes and having a thicker or heavier first pane (outer pane) as compared to the second and third panes and/or an edge seal force not exceeding 1.2 N/m, when measured in accordance with prEN 16612.

Abstract: A hurricane-resistant laminated pane comprises a first sheet of thermally strengthened glass having a thickness in the range of from 2 to 24 mm, a second sheet of chemically tempered glass having a thickness in the range of from 0.3 to 1 mm and a surface compression of at least 100 MPa, and a polymer interlayer adhered between the first sheet and the second sheet. A process for making such a pane and a window comprising such a pane are also disclosed.

Abstract: A hurricane-resistant laminated pane comprises a first sheet of thermally strengthened glass having a thickness in the range of from 2 to 24 mm, a second sheet of untempered glass having a thickness in the range of from 0.3 to 1 mm, and a polymer interlayer adhered between the first sheet and the second sheet. A process for making such a pane and a window comprising such a pane are also disclosed.

Abstract: A laminated pane for a window includes (1) a first sheet having a first thickness and a first coefficient of thermal expansion (CTE), (2) a second sheet of an inorganic glass having a second thickness and a second CTE, and (3) a polymer interlayer adhered between the first sheet and the second sheet including a layer of a first polymer material having a first elastic modulus and a layer of a second polymer material having a second elastic modulus, wherein the first CTE is greater than the second CTE, the second thickness is in the range of from 1 down to 0.3 mm, and the first elastic modulus is more than 20 times the second elastic modulus.

Abstract: Laminated structures include a thin glass sheet with a thickness of less than 600 ?m being attached to a metal sheet with an adhesive layer including a thickness of about 100 ?m or less. These laminated structures can include planar or curved shapes. Methods of manufacturing a laminated structure are also provided including the step of attaching a glass sheet with a thickness of less than 600 ?m to a metal sheet with an adhesive layer including a thickness of about 300 ?m or less.

Abstract: An insulated glass unit includes a first pane, a second pane, and a third pane between the first and second panes, and a first sealed gap space between the first pane and the third pane and a second sealed gap space between the second pane and the third pane. The third pane comprises first glass sheet having a coefficient of thermal expansion (CTE) over a temperature range 0 to about 300° C. of less than about 70×10?7/° C.

Abstract: A laminate structure having a first chemically strengthened glass layer, a second chemically strengthened glass layer, and a polymer interlayer structure intermediate the first and second glass layers. The polymer interlayer structure can include a first polymeric layer adjacent to the first glass layer, a second polymeric layer adjacent to the second glass layer, and a polymeric rigid core intermediate the first and second polymeric layers.

Abstract: An insulated glass unit is described and includes at least a first glass layer, a second glass layer and a third glass layer disposed therebetween. The third glass layer is separated from the first glass layer and the second glass layer by first and second sealed gap spaces. The third glass layer has a low CTE as compared to the CTE of the first and/or second glass layers. In some instances, the third glass layer has a CTE of less than 70×10?7/° C. over a temperature range of 0-300° C.

Abstract: Example methods of manufacturing a glass mirror apparatus includes the step of providing a chemically strengthened glass sheet with a thickness of less than or equal to about 2 mm. The method further includes the step of applying a reflective layer to the second major surface of the glass sheet to provide a first glass mirror. In further examples, a glass mirror apparatus comprises a chemically strengthened glass sheet with a thickness of less than or equal to about 2 mm. A reflective layer applied to the second major surface of the glass sheet to provide a first glass mirror.

Abstract: Laminated structures include a thin glass sheet with a thickness of less than 600 ?m being attached to a metal sheet with an adhesive layer including a thickness of about 100 ?m or less. These laminated structures can include planar or curved shapes. Methods of manufacturing a laminated structure are also provided including the step of attaching a glass sheet with a thickness of less than 600 ?m to a metal sheet with an adhesive layer including a thickness of about 300 ?m or less.

Abstract: Described herein are apparatuses for holding a substrate in a near vertical position, wherein the design minimizes substrate sag while allowing the substrate to expand and contract under varying thermal conditions. The apparatus minimizes the stress on the substrate, preventing breakage of or damage to the substrate while it undergoes coating and other thermal processes.

Abstract: A laminate structure having a first chemically strengthened glass layer, a second chemically strengthened glass layer, and a polymer interlayer structure intermediate the first and second glass layers. The polymer interlayer structure can include a first polymeric layer adjacent to the first glass layer, a second polymeric layer adjacent to the second glass layer, and a polymeric rigid core intermediate the first and second polymeric layers.

Abstract: A laminate structure having a first chemically strengthened glass layer, a second chemically strengthened glass layer, and a polymer interlayer structure intermediate the first and second glass layers. The polymer interlayer structure can include a first polymeric layer adjacent to the first glass layer, a second polymeric layer adjacent to the second glass layer, and a polymeric rigid core intermediate the first and second polymeric layers.

Abstract: Disclosed herein are methods for making asymmetric laminate structures and methods for reducing bow in asymmetric laminate structures, the methods comprising differentially heating the laminate structures during lamination or differentially cooling the laminate structures after lamination. Also disclosed herein are methods for reducing bow in asymmetric laminate structures, the methods comprising subjecting at least one substrate in the laminate structure to asymmetric tempering or annealing prior to lamination. Further disclosed herein are laminate structures made according to such methods.

Abstract: Disclosed herein are methods for making asymmetric laminate structures and methods for reducing bow in asymmetric laminate structures, the methods comprising differentially heating the laminate structures during lamination or differentially cooling the laminate structures after lamination. Also disclosed herein are methods for reducing bow in asymmetric laminate structures, the methods comprising subjecting at least one substrate in the laminate structure to asymmetric tempering or annealing prior to lamination. Further disclosed herein are laminate structures made according to such methods.

Abstract: According to embodiments, there is provided a method (300) of controlling a first melt accumulator (121). The first melt accumulator (121) is part of an injection unit (100), the injection unit (100) including an extruder (102) for preparing molding material and a second melt accumulator (123). The first melt accumulator (121) and the second melt accumulator (123) are configured to sequentially receive molding material from the extruder (102). The extruder (102) is being operable to produce molding material in at least near continuous manner, both the first melt accumulator (121) and the second melt accumulator (123) being associated with a respective shot size set-point. The method comprises detecting (310) an indication of an out-of-boundary condition associated with operation the first melt accumulator (121); responsive to said detecting (310), controlling (320) the first melt accumulator (121) to continue accepting molding material beyond its respective shot size set-point.

Abstract: Example methods of manufacturing a glass mirror apparatus includes the step of providing a chemically strengthened glass sheet with a thickness of less than or equal to about 2 mm. The method further includes the step of applying a reflective layer to the second major surface of the glass sheet to provide a first glass mirror. In further examples, a glass mirror apparatus comprises a chemically strengthened glass sheet with a thickness of less than or equal to about 2 mm. A reflective layer applied to the second major surface of the glass sheet to provide a first glass mirror.

Abstract: Laminated structures include a thin glass sheet with a thickness of less than 600 ?m being attached to a metal sheet with an adhesive layer including a thickness of about 100 ?m or less. These laminated structures can include planar or curved shapes. Methods of manufacturing a laminated structure are also provided including the step of attaching a glass sheet with a thickness of less than 600 ?m to a metal sheet with an adhesive layer including a thickness of about 300 ?m or less.

Abstract: According to embodiments, there is provided a method (300) of controlling a first melt accumulator (121). The first melt accumulator (121) is part of an injection unit (100), the injection unit (100) including an extruder (102) for preparing molding material and a second melt accumulator (123). The first melt accumulator (121) and the second melt accumulator (123) are configured to sequentially receive molding material from the extruder (102). The extruder (102) is being operable to produce molding material in at least near continuous manner, both the first melt accumulator (121) and the second melt accumulator (123) being associated with a respective shot size set-point. The method comprises detecting (310) an indication of an out-of-boundary condition associated with operation the first melt accumulator (121); responsive to said detecting (310), controlling (320) the first melt accumulator (121) to continue accepting molding material beyond its respective shot size set-point.